Your search keyword '"Young-Jun Koo"' showing total 7 results

1. Higher coactivations of lower limb muscles increase stability during walking on slippery ground in forward dynamics musculoskeletal simulation

Author

Young-Jun Koo, Jemin Hwangbo, and Seungbum Koo

Subjects

Medicine, Science

Abstract

Abstract The energy efficiency theory of human bipedal locomotion has been widely accepted as a neuro-musculoskeletal control method. However, coactivation of agonist and antagonist muscles in the lower limb has been observed during various limb movements, including walking. The emergence of this coactivation cannot be explained solely by the energy efficiency theory and remains a subject of debate. To shed light on this, we investigated the role of muscle coactivations in walking stability using a forward dynamics musculoskeletal simulation combined with neural-network-based gait controllers. Our study revealed that a gait controller with minimal muscle activations had a high probability of falls under challenging gait conditions such as slippery ground and uneven terrain. Lower limb muscle coactivations emerged in the process of gait controller training on slippery ground. Controllers with physiological coactivation levels demonstrated a significantly reduced probability of falls. Our results suggest that achieving stable walking requires muscle coactivations beyond the minimal level of muscle energy. This study implies that coactivations likely emerge to maintain gait stability under challenging conditions, and both coactivation and energy optimization of lower limb muscles should be considered when exploring the foundational control mechanisms of human walking.

Published

2023

2. 13.4 A 48GB 16-High 1280GB/s HBM3E DRAM with All-Around Power TSV and a 6-Phase RDQS Scheme for TSV Area Optimization.

Author

Jinhyung Lee, Kyungjun Cho, Chang Kwon Lee, Yeonho Lee 0002, Jae-Hyung Park, Su-Hyun Oh, Yucheon Ju, Chunseok Jeong, Ho Sung Cho, Jaeseung Lee, Tae-Sik Yun, Jin Hee Cho, Sangmuk Oh, Junil Moon, Young-Jun Park, Hong-Seok Choi, In-Keun Kim, Seung Min Yang, Sun-Yeol Kim, Jaemin Jang, Jinwook Kim, Seong-Hee Lee, Younghyun Jeon, Juhyung Park, Tae-Kyun Kim 0002, Dongyoon Ka, Sanghoon Oh, Jinse Kim, Junyeol Jeon, Seonhong Kim, Kyeong Tae Kim, Taeho Kim, Hyeonjin Yang, Dongju Yang, Minseop Lee, Heewoong Song, Dongwook Jang, Junghyun Shin, Hyunsik Kim, Chang-Ki Baek, Hajun Jeong, Jongchan Yoon, Seung-Kyun Lim, Kyo Yun Lee, Young Jun Koo, Myeong-Jae Park, Joohwan Cho, and Jonghwan Kim

Published

2024

3. The effect of noise injection method on DRL-based controller robustness of human gait model.

Author

Young-Jun Koo, Jeong-Woo Lee, Bumho Kim, and Yung-Joon Jung

Published

2023

4. A 192-Gb 12-High 896-GB/s HBM3 DRAM with a TSV Auto-Calibration Scheme and Machine-Learning-Based Layout Optimization.

Author

Myeong-Jae Park, Ho Sung Cho, Tae-Sik Yun, Sangjin Byeon, Young Jun Koo, Sang-Sic Yoon, Dong-Uk Lee, Seokwoo Choi, Ji Hwan Park, Jinhyung Lee, Kyungjun Cho, Junil Moon, Byung Kuk Yoon, Young Jun Park, Sangmuk Oh, Chang Kwon Lee, Tae-Kyun Kim 0001, Seong-Hee Lee, Hyun-Woo Kim, Yucheon Ju, Seung-Kyun Lim, Seung Geun Baek, Kyo Yun Lee, Sang Hun Lee, Woo Sung We, Seungchan Kim, Yongseok Choi, Seong-Hak Lee, Seung Min Yang, Gunho Lee, In-Keun Kim, Younghyun Jeon, Jae-Hyung Park, Jong Chan Yun, Chanhee Park, Sun-Yeol Kim, Sungjin Kim, Dong-Yeol Lee, Su-Hyun Oh, Taejin Hwang, Junghyun Shin, Yunho Lee, Hyunsik Kim, Jaeseung Lee, Youngdo Hur, Sangkwon Lee, Jieun Jang, Junhyun Chun, and Joohwan Cho

Published

2022

5. A 192-Gb 12-High 896-GB/s HBM3 DRAM With a TSV Auto-Calibration Scheme and Machine-Learning-Based Layout Optimization

Author

Myeong-Jae Park, Jinhyung Lee, Kyungjun Cho, Jihwan Park, Junil Moon, Sung-Hak Lee, Tae-Kyun Kim, Sanghoon Oh, Seokwoo Choi, Yongsuk Choi, Ho Sung Cho, Taesik Yun, Young Jun Koo, Jae-Seung Lee, Byung-Kuk Yoon, Young-Jun Park, Sangmuk Oh, Chang Kwon Lee, Seong-Hee Lee, Hyun-Woo Kim, Yucheon Ju, Seung-Kyun Lim, Kyo Yun Lee, Sang-Hoon Lee, Woo Sung We, Seungchan Kim, Seung Min Yang, Keonho Lee, In-Keun Kim, Younghyun Jeon, Jae-Hyung Park, Jong Chan Yun, Seonyeol Kim, Dong-Yeol Lee, Su-Hyun Oh, Jung-Hyun Shin, Yeonho Lee, Jieun Jang, and Joohwan Cho

Subjects

Electrical and Electronic Engineering

Published

2023

6. Influences of Partial Anterior Cruciate Ligament Injury on Anterior Cruciate Ligament Tensional Force and Kinematic Stability During Walking

Author

Young-Jun Koo, Jong Keun Seon, Giuk Lee, and Seungbum Koo

Subjects

Joint Instability, Knee Joint, Rotation, Physiology (medical), Anterior Cruciate Ligament Injuries, Biomedical Engineering, Cadaver, Humans, Walking, Anterior Cruciate Ligament, Range of Motion, Articular, Biomechanical Phenomena

Abstract

Injuries in the anterior cruciate ligament (ACL), including partial tear and lengthening of the ACL, change the dynamic function of the knee. However, there is a lack of information on the effect of ACL partial tear on knee kinematics during walking. This study aimed to investigate the effects of different levels of ACL injuries on knee stability and ACL tensional force to identify the critical injury level. Motion data of five normal subjects were acquired along with the ground reaction force. A knee model with 14 ligaments was developed using cadaveric specimen data. The initial length and stiffness of the ACL were changed to develop ACL-injured knee models. Musculoskeletal simulations of the knee models were performed using the measured gait data. The average tibial anterior translation increased significantly by 2.6 ± 0.7 mm when the ACL stiffness decreased to 25% of its original stiffness. The average tibial anterior translation increased significantly by 2.6 ± 0.3 mm at an increase in initial length of 10%. The knee with partial ACL tear had a nonlinear decrease in ACL forces owing to the increase in the level of ACL injury, while the knee with ACL lengthening had linear decreased ACL forces. The partial tear of the ACL caused translational instability, while the complete tear caused both rotational and translational instabilities during the musculoskeletal walking simulation. This study presents the effects of partial ACL injuries on joint kinematics and ACL tensional force during the dynamic motion of walking.

Published

2022

7. Influences of Partial Anterior Cruciate Ligament Injury on Anterior Cruciate Ligament Tensional Force and Kinematic Stability During Walking.

Author

Young-Jun Koo, Jong Keun Seon, Giuk Lee, and Seungbum Koo

Abstract

Injuries in the anterior cruciate ligament (ACL), including partial tear and lengthening of the ACL, change the dynamic function of the knee. However, there is a lack of information on the effect of ACL partial tear on knee kinematics during walking. This study aimed to investigate the effects of different levels of ACL injuries on knee stability and ACL tensional force to identify the critical injury level. Motion data of five normal subjects were acquired along with the ground reaction force. A knee model with 14 ligaments was developed using cadaveric specimen data. The initial length and stiffness of the ACL were changed to develop ACL-injured knee models. Musculoskeletal simulations of the knee models were performed using the measured gait data. The average tibial anterior translation increased significantly by 2.6 ± 0.7 mm when the ACL stiffness decreased to 25% of its original stiffness. The average tibial anterior translation increased significantly by 2.6 ± 0.3 mm at an increase in initial length of 10%. The knee with partial ACL tear had a nonlinear decrease in ACL forces owing to the increase in the level of ACL injury, while the knee with ACL lengthening had linear decreased ACL forces. The partial tear of the ACL caused translational instability, while the complete tear caused both rotational and translational instabilities during the musculoskeletal walking simulation. This study presents the effects of partial ACL injuries on joint kinematics and ACL tensional force during the dynamic motion of walking. [ABSTRACT FROM AUTHOR]

Published

2023